Current and Resistance

1. Current and Resistance CHAPTER 19

2. The nature of electricity • How does the energy generated by wind farms get to people’s houses to power their appliances?

3. Current • Current is the rate of change of electric charge • A current exits whenever there is a net movement of electric charge through a medium • The unit for current is the ampere • 1 ampere= 1 Coulomb second

4. Sample Question p. 695 #2 • In a particular television tube, the beam current is 60 µA. How long does it take for 3.75 x 1014 electrons to strike the screen? • First calculate the electric charge of 3.75 x 1014 electrons. • 1 electron has a charge of 1.60 x 10-19 C • (3.75 x 1014 ) (1.60 x 10-19 C)= 6 x 10-5 C

5. Sources and Types of Current • Batteries and generators work by converting other forms of energy into electrical potential energy • Batteries convert chemical energy into electrical potential energy • Generators convert mechanical energy (KE and PE) into electrical potential energy

6. Potential Difference • Potential Difference, ΔV, is the driving force behind current • Increasing potential difference results in a greater current • i.e. using a 9.0 V battery generates a greater current than a 6.0 V battery • V is measured in volts • 1 volt= 1 Joule/Coulomb

7. Resistance • Some conductors allow charges to move through them more easily than others • The opposition to the motion of charge through a conductor is the conductor’s resistance • The unit for resistance is the ohm (Ω) • Ohm’s Law:

8. Ohm’s Law • Resistance is inversely proportional to current • As the resistance increases, the current decreases • For most materials, resistance is independent of V. • Therefore, changing V affects the current, not the resistance

9. Factors that affect resistance (p. 703)

10. Sample Problem p. 703 #6 • The current in a certain resistor is 0.50 A when it is connected to a potential difference of 110 v. What is the current in this same resistor if • a. The operating potential difference is 90.0 V? • b. The operating potential difference is 130 V?

11. p. 703 #6 • I= 0.50 A, V = 110 V • We’re looking for the new current if the potential difference is changed • According to Ohm’s Law: • We’re missing R. Let’s find it 

12. p. 703 #6 • Let’s find the new current for each potential difference • A. • B.

13. Superconductors • Superconductors have zero resistance below a certain temperature called the critical temperature. • Once a current is established in a superconductor it will continue even if the potential difference is removed

14. Electric Power • Electric power is the rate at which electrical energy is converted to other types of energy • Power is measured in Watts

15. Circuits and Circuit Elements Chapter 20

16. Schematic Diagrams (p. 731) • A diagram that depicts the construction of an electrical apparatus is a schematic diagram

17. Electric Circuits • An electric circuit is a path through which charges can be conducted

18. Necessary Parts of an electrical circuit • The wire: Current flows through the wire • The resistor: Can be a light bulb • The emf source: Provides the potential difference…it’s usually a battery

19. Series Circuits • When resistors are connected in series, all the charges have to follow a single path • When one light bulb goes out, they all go out 

20. Series Circuits • When resistors are connected in series, the current in each resistor is the same!!! • The total current in the circuit depends on how many resistors are present • The equivalent resistance is the sum of the circuit’s resistances • THE EQUIVALENT RESISTANCE SHOULD ALWAYS BE GREATER THAN THE LARGEST RESISTANCE IN THE CIRCUIT

21. Series Current • To find the total current in the circuit, first find the equivalent resistance and then use Ohm’s Law • Although the current in each resistor has to be the same, the potential difference doesn’t have to be the same.

22. Sample Problem p. 739 #2 • A 4.0 Ω resistor, an 8.0 Ω resistor and a 12.0 Ω resistor are connected in series with a 24.0 V battery • A. Calculate the equivalent resistance • B. Calculate the current in the circuit • What is the current in each resistor? • For resistors in series, the current in each resistor is the same…so the answer is 1.0 A

23. Parallel Circuits • A parallel circuit is a wiring arrangement that provides alternative pathways for the movement of charges

24. Parallel Circuits • The total current in a parallel circuit is equal to the sum of the current in each resistor • The equivalent resistance in a parallel circuit is calculated using the following equation • The potential difference across each resistor is the same

25. Sample Problem p. 744 # 2 • An 18.0 Ω, 9.00 Ω, and 6.00 Ω resistor are connected in parallel to an emf source. A current of 4.0 A is in the 9.00 Ω resistor. • a. Calculate the equivalent resistance of the circuit. • B. What is the potential difference across the source? • C. Calculate the current in the other resistors

26. Complex Circuits • Most circuits have both series and parallel components

27. Complex Circuits (p. 747) • To determine the equivalent resistance for a complex circuit, you have to simplify the circuit into groups of series and parallel resistors • Sample Problem 20C (p. 747) Since the 6.0 Ω and 2.0 Ω resistor are connected in series, their equivalent resistance is 8.0 Ω

28. Sample Problem 20C (p. 747) • The new 8.0 Ω resistor and 4.0 Ω resistor are connected in parallel. Their equivalent resistance can be found using the following equation: Req= 2.7 Ω

29. Sample Problem 20 C (p. 747) • Finally, the last three resistors are connected in series so their equivalent resistance= 9.0 Ω + 2.7 Ω + 1.0 Ω= 12.7 Ω • The circuit can now be redrawn with the equivalent resistance connected to the original emf source

30. Determining I and V for a resistor in a complex circuit • To find the current and/or potential difference across a particular resistor in a complex circuit you must first find the equivalent resistance for the circuit • Then you must rebuild the circuit in steps and calculate the current and potential difference for each group

31. Sample Problem 20D (p. 749) • Sample problem 20D is a continuation of sample problem 20C. • We already determined the equivalent resistance for the circuit…12.7 Ω • Next we need to rebuild the circuit and find the potential difference and current for each group.

32. The total current in the circuit

33. Rebuilding the circuit • Work backward to find the current and potential difference for the next group. • These three resistors are connected in series. That means the current across all three resistors is the same (I=0.71 A). • We only care about the middle resistor because it’s the only one that leads to the 2.0 Ω resistor

34. Rebuilding the circuit • Work backward to find the current and potential difference for the next group. • The 2.7 Ω resistor is composed of the 8.0 Ω and 4.0 Ω resistors in parallel • This means they have the same potential difference. (V=1.9 V) • We only care about the 8.0 Ω resistor because it’s the only one that leads to the 2.0 Ω resistor

35. Rebuilding the circuit • Work backward to find the current and potential difference for the next group. • The 8.0 Ω resistor is composed of the 6.0 Ω and 2.0 Ω resistors connected in series. • This means they share the same current (I=0.24 A) • Solve for the potential difference and you’re done 

36. http://alkalinebatteries.us/images/batteries3.jpg • http://www.renewablepowernews.com/wp-content/uploads/2008-04-wind-farm-hawaii22.jpg